// zipstream Library License:
// --------------------------
//
// The zlib/libpng License Copyright (c) 2003 Jonathan de Halleux.
//
// This software is provided 'as-is', without any express or implied warranty. In no event will the authors be held liable for any damages arising from the use of this software.
//
// Permission is granted to anyone to use this software for any purpose, including commercial applications, and to alter it and redistribute it freely, subject to the following restrictions:
//
// 1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required.
//
// 2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software.
//
// 3. This notice may not be removed or altered from any source distribution
//
//
// Author: Jonathan de Halleux, dehalleux@pelikhan.com, 2003   (original zlib stream)
// Author: David Weese, dave.weese@gmail.com, 2014             (extension to parallel block-wise compression in bgzf format)

#ifndef INCLUDE_SEQAN_STREAM_IOSTREAM_BGZF_H_
#define INCLUDE_SEQAN_STREAM_IOSTREAM_BGZF_H_

namespace seqan {

const unsigned BGZF_MAX_BLOCK_SIZE = 64 * 1024;
const unsigned BGZF_BLOCK_HEADER_LENGTH = 18;
const unsigned BGZF_BLOCK_FOOTER_LENGTH = 8;
const unsigned ZLIB_BLOCK_OVERHEAD = 5; // 5 bytes block overhead (see 3.2.4. at http://www.gzip.org/zlib/rfc-deflate.html)

// Reduce the maximal input size, such that the compressed data
// always fits in one block even for level Z_NO_COMPRESSION.
const unsigned BGZF_BLOCK_SIZE = BGZF_MAX_BLOCK_SIZE - BGZF_BLOCK_HEADER_LENGTH - BGZF_BLOCK_FOOTER_LENGTH - ZLIB_BLOCK_OVERHEAD;

// ===========================================================================
// Classes
// ===========================================================================

// --------------------------------------------------------------------------
// Class basic_bgzf_streambuf
// --------------------------------------------------------------------------

template<
    typename Elem,
    typename Tr = std::char_traits<Elem>,
    typename ElemA = std::allocator<Elem>,
    typename ByteT = char,
    typename ByteAT = std::allocator<ByteT>
>
class basic_bgzf_streambuf : public std::basic_streambuf<Elem, Tr>
{
public:
    typedef std::basic_ostream<Elem, Tr>& ostream_reference;
    typedef ElemA char_allocator_type;
    typedef ByteT byte_type;
    typedef ByteAT byte_allocator_type;
    typedef byte_type* byte_buffer_type;
    typedef typename Tr::char_type char_type;
    typedef typename Tr::int_type int_type;

    typedef ConcurrentQueue<size_t, Suspendable<Limit> > TJobQueue;

    struct OutputBuffer
    {
        char    buffer[BGZF_MAX_BLOCK_SIZE];
        size_t  size;
    };

    struct BufferWriter
    {
        ostream_reference ostream;

        BufferWriter(ostream_reference ostream) :
            ostream(ostream)
        {}

        bool operator() (OutputBuffer const & outputBuffer)
        {
            ostream.write(outputBuffer.buffer, outputBuffer.size);
            return ostream.good();
        }
    };

    struct CompressionJob
    {
        typedef std::vector<char_type, char_allocator_type> TBuffer;

        TBuffer         buffer;
        size_t          size;
        OutputBuffer    *outputBuffer;

        CompressionJob() :
            buffer(BGZF_BLOCK_SIZE / sizeof(char_type), 0),
            size(0),
            outputBuffer(NULL)
        {}
    };

    // string of recycable jobs
    size_t                  numThreads;
    size_t                  numJobs;
    String<CompressionJob>  jobs;
    TJobQueue               jobQueue;
    TJobQueue               idleQueue;
    Serializer<
        OutputBuffer,
        BufferWriter>       serializer;

    size_t                  currentJobId;
    bool                    currentJobAvail;


    struct CompressionThread
    {
        basic_bgzf_streambuf            *streamBuf;
        CompressionContext<BgzfFile>    compressionCtx;
        size_t                          threadNum;

        void operator()()
        {
            ScopedReadLock<TJobQueue> readLock(streamBuf->jobQueue);
            ScopedWriteLock<TJobQueue> writeLock(streamBuf->idleQueue);

            // wait for a new job to become available
            bool success = true;
            while (success)
            {
                size_t jobId = -1;
                if (!popFront(jobId, streamBuf->jobQueue))
                    return;

                CompressionJob &job = streamBuf->jobs[jobId];

                // compress block with zlib
                job.outputBuffer->size = _compressBlock(
                    job.outputBuffer->buffer, sizeof(job.outputBuffer->buffer),
                    &job.buffer[0], job.size, compressionCtx);

                success = releaseValue(streamBuf->serializer, job.outputBuffer);
                appendValue(streamBuf->idleQueue, jobId);
            }
        }
    };

    // array of worker threads
    using TFuture = decltype(std::async(CompressionThread{nullptr, CompressionContext<BgzfFile>{}, static_cast<size_t>(0)}));
    std::vector<TFuture>         threads;

    basic_bgzf_streambuf(ostream_reference ostream_,
                         size_t numThreads = 16,
                         size_t jobsPerThread = 8) :
        numThreads(numThreads),
        numJobs(numThreads * jobsPerThread),
        jobQueue(numJobs),
        idleQueue(numJobs),
        serializer(ostream_, numThreads * jobsPerThread)
    {
        resize(jobs, numJobs, Exact());
        currentJobId = 0;

        lockWriting(jobQueue);
        lockReading(idleQueue);
        setReaderWriterCount(jobQueue, numThreads, 1);
        setReaderWriterCount(idleQueue, 1, numThreads);

        for (unsigned i = 0; i < numJobs; ++i)
        {
            bool success = appendValue(idleQueue, i);
            ignoreUnusedVariableWarning(success);
            SEQAN_ASSERT(success);
        }

        for (size_t i = 0; i < numThreads; ++i)
        {
            threads.push_back(std::async(std::launch::async, CompressionThread{this, CompressionContext<BgzfFile>{}, i}));
        }

        currentJobAvail = popFront(currentJobId, idleQueue);
        SEQAN_ASSERT(currentJobAvail);

        CompressionJob &job = jobs[currentJobId];
        job.outputBuffer = aquireValue(serializer);
        this->setp(&job.buffer[0], &job.buffer[0] + (job.buffer.size() - 1));
    }

    ~basic_bgzf_streambuf()
    {
        // the buffer is now (after addFooter()) and flush will append the empty EOF marker
        flush(true);

        unlockWriting(jobQueue);
        unlockReading(idleQueue);
    }

    bool compressBuffer(size_t size)
    {
        // submit current job
        if (currentJobAvail)
        {
            jobs[currentJobId].size = size;
            appendValue(jobQueue, currentJobId);
        }

        // recycle existing idle job
        if (!(currentJobAvail = popFront(currentJobId, idleQueue)))
            return false;

        jobs[currentJobId].outputBuffer = aquireValue(serializer);

        return serializer;
    }

    int_type overflow(int_type c)
    {
        int w = static_cast<int>(this->pptr() - this->pbase());
        if (c != EOF)
        {
            *this->pptr() = c;
            ++w;
        }
        if (compressBuffer(w))
        {
            CompressionJob &job = jobs[currentJobId];
            this->setp(&job.buffer[0], &job.buffer[0] + (job.buffer.size() - 1));
            return c;
        }
        else
        {
            return EOF;
        }
    }

    std::streamsize flush(bool flushEmptyBuffer = false)
    {
        int w = static_cast<int>(this->pptr() - this->pbase());
        if ((w != 0 || flushEmptyBuffer) && compressBuffer(w))
        {
            CompressionJob &job = jobs[currentJobId];
            this->setp(&job.buffer[0], &job.buffer[0] + (job.buffer.size() - 1));
        }
        else
        {
            w = 0;
        }

        // wait for running compressor threads
        waitForMinSize(idleQueue, numJobs - 1);

        serializer.worker.ostream.flush();
        return w;
    }

    int sync()
    {
        if (this->pptr() != this->pbase())
        {
            int c = overflow(EOF);
            if (c == EOF)
                return -1;
        }
        return 0;
    }

    void addFooter()
    {
        // we flush the filled buffer here, so that an empty (EOF) buffer is flushed in the d'tor
        if (this->pptr() != this->pbase())
            overflow(EOF);
    }

    // returns a reference to the output stream
    ostream_reference get_ostream() const    { return serializer.worker.ostream; };
};

// --------------------------------------------------------------------------
// Class basic_unbgzf_streambuf
// --------------------------------------------------------------------------

template<
    typename Elem,
    typename Tr = std::char_traits<Elem>,
    typename ElemA = std::allocator<Elem>,
    typename ByteT = char,
    typename ByteAT = std::allocator<ByteT>
>
class basic_unbgzf_streambuf :
    public std::basic_streambuf<Elem, Tr>
{
public:
    typedef std::basic_istream<Elem, Tr>& istream_reference;
    typedef ElemA char_allocator_type;
    typedef ByteT byte_type;
    typedef ByteAT byte_allocator_type;
    typedef byte_type* byte_buffer_type;
    typedef typename Tr::char_type char_type;
    typedef typename Tr::int_type int_type;
    typedef typename Tr::off_type off_type;
    typedef typename Tr::pos_type pos_type;

    typedef std::vector<char_type, char_allocator_type>     TBuffer;
    typedef ConcurrentQueue<int, Suspendable<Limit> >       TJobQueue;

    static const size_t MAX_PUTBACK = 4;

    struct Serializer
    {
        istream_reference   istream;
        std::mutex          lock;
        IOError             *error;
        off_type            fileOfs;

        Serializer(istream_reference istream) :
            istream(istream),
            error(NULL),
            fileOfs(0u)
        {}

        ~Serializer()
        {
            delete error;
        }
    };

    Serializer serializer;

    struct DecompressionJob
    {
        typedef std::vector<byte_type, byte_allocator_type> TInputBuffer;

        TInputBuffer            inputBuffer;
        TBuffer                 buffer;
        off_type                fileOfs;
        int                     size;
        unsigned                compressedSize;

        std::mutex              cs;
        std::condition_variable readyEvent;
        bool                    ready;

        DecompressionJob() :
            inputBuffer(BGZF_MAX_BLOCK_SIZE, 0),
            buffer(MAX_PUTBACK + BGZF_MAX_BLOCK_SIZE / sizeof(char_type), 0),
            fileOfs(),
            size(0),
            cs(),
            readyEvent(),
            ready(true)
        {}

        // TODO(rrahn): Do we need a copy constructor for the decompression job.
        DecompressionJob(DecompressionJob const &other) :
            inputBuffer(other.inputBuffer),
            buffer(other.buffer),
            fileOfs(other.fileOfs),
            size(other.size),
            cs(),
            readyEvent(),
            ready(other.ready)
        {}
    };

    // string of recycable jobs
    size_t                      numThreads;
    size_t                      numJobs;
    String<DecompressionJob>    jobs;
    TJobQueue                   runningQueue;
    TJobQueue                   todoQueue;
    int                         currentJobId;

    struct DecompressionThread
    {
        basic_unbgzf_streambuf          *streamBuf;
        CompressionContext<BgzfFile>    compressionCtx;

        void operator()()
        {
            ScopedReadLock<TJobQueue> readLock(streamBuf->todoQueue);
            ScopedWriteLock<TJobQueue> writeLock(streamBuf->runningQueue);

            // wait for a new job to become available
            while (true)
            {
                int jobId = -1;
                if (!popFront(jobId, streamBuf->todoQueue))
                    return;

                DecompressionJob &job = streamBuf->jobs[jobId];
                size_t tailLen = 0;

                // typically the idle queue contains only ready jobs
                // however, if seek() fast forwards running jobs into the todoQueue
                // the caller defers the task of waiting to the decompression threads
                if (!job.ready)
                {
                    std::unique_lock<std::mutex> lock(job.cs);
                    job.readyEvent.wait(lock, [&job]{return job.ready;});
                    SEQAN_ASSERT_EQ(job.ready, true);
                }

                {
                    std::lock_guard<std::mutex> scopedLock(streamBuf->serializer.lock);

                    if (streamBuf->serializer.error != NULL)
                        return;

                    // remember start offset (for tellg later)
                    job.fileOfs = streamBuf->serializer.fileOfs;
                    job.size = -1;
                    job.compressedSize = 0;

                    // only load if not at EOF
                    if (job.fileOfs != -1)
                    {
                        // read header
                        streamBuf->serializer.istream.read(
                            (char*)&job.inputBuffer[0],
                            BGZF_BLOCK_HEADER_LENGTH);

                        if (!streamBuf->serializer.istream.good())
                        {
                            streamBuf->serializer.fileOfs = -1;
                            if (streamBuf->serializer.istream.eof())
                                goto eofSkip;
                            streamBuf->serializer.error = new IOError("Stream read error.");
                            return;
                        }

                        // check header
                        if (!_bgzfCheckHeader(&job.inputBuffer[0]))
                        {
                            streamBuf->serializer.fileOfs = -1;
                            streamBuf->serializer.error = new IOError("Invalid BGZF block header.");
                            return;
                        }

                        // extract length of compressed data
                        tailLen = _bgzfUnpack16(&job.inputBuffer[0] + 16) + 1u - BGZF_BLOCK_HEADER_LENGTH;

                        // read compressed data and tail
                        streamBuf->serializer.istream.read(
                            (char*)&job.inputBuffer[0] + BGZF_BLOCK_HEADER_LENGTH,
                            tailLen);

                        if (!streamBuf->serializer.istream.good())
                        {
                            streamBuf->serializer.fileOfs = -1;
                            if (streamBuf->serializer.istream.eof())
                                goto eofSkip;
                            streamBuf->serializer.error = new IOError("Stream read error.");
                            return;
                        }

                        job.compressedSize = BGZF_BLOCK_HEADER_LENGTH + tailLen;
                        streamBuf->serializer.fileOfs += job.compressedSize;
                        job.ready = false;

                    eofSkip:
                        streamBuf->serializer.istream.clear(
                            streamBuf->serializer.istream.rdstate() & ~std::ios_base::failbit);
                    }

                    if (!appendValue(streamBuf->runningQueue, jobId))
                    {
                        // signal that job is ready
                        {
                            std::unique_lock<std::mutex> lock(job.cs);
                            job.ready = true;
                        }
                        job.readyEvent.notify_all();
                        return;  // Terminate this thread.
                    }
                }

                if (!job.ready)
                {
                    // decompress block
                    job.size = _decompressBlock(
                        &job.buffer[0] + MAX_PUTBACK, capacity(job.buffer),
                        &job.inputBuffer[0], job.compressedSize, compressionCtx);

                    // signal that job is ready
                    {
                        std::unique_lock<std::mutex> lock(job.cs);
                        job.ready = true;
                    }
                    job.readyEvent.notify_all();
                }
            }
        }
    };

    // array of worker threads
    using TFuture = decltype(std::async(DecompressionThread{nullptr, CompressionContext<BgzfFile>{}}));
    std::vector<TFuture> threads;
    TBuffer              putbackBuffer;

    basic_unbgzf_streambuf(istream_reference istream_,
                           size_t numThreads = 16,
                           size_t jobsPerThread = 8) :
        serializer(istream_),
        numThreads(numThreads),
        numJobs(numThreads * jobsPerThread),
        runningQueue(numJobs),
        todoQueue(numJobs),
        putbackBuffer(MAX_PUTBACK)
    {
        resize(jobs, numJobs, Exact());
        currentJobId = -1;

        lockReading(runningQueue);
        lockWriting(todoQueue);
        setReaderWriterCount(runningQueue, 1, numThreads);
        setReaderWriterCount(todoQueue, numThreads, 1);

        for (unsigned i = 0; i < numJobs; ++i)
        {
            bool success = appendValue(todoQueue, i);
            ignoreUnusedVariableWarning(success);
            SEQAN_ASSERT(success);
        }

        for (unsigned i = 0; i < numThreads; ++i)
        {
            threads.push_back(std::async(std::launch::async, DecompressionThread{this, CompressionContext<BgzfFile>{}}));
        }
    }

    ~basic_unbgzf_streambuf()
    {
        unlockWriting(todoQueue);
        unlockReading(runningQueue);
    }

    int_type underflow()
    {
        // no need to use the next buffer?
        if (this->gptr() && this->gptr() < this->egptr())
            return Tr::to_int_type(*this->gptr());

        size_t putback = this->gptr() - this->eback();
        if (putback > MAX_PUTBACK)
            putback = MAX_PUTBACK;

        // save at most MAX_PUTBACK characters from previous page to putback buffer
        if (putback != 0)
            std::copy(
                this->gptr() - putback,
                this->gptr(),
                &putbackBuffer[0]);

        if (currentJobId >= 0)
            appendValue(todoQueue, currentJobId);

        while (true)
        {
            if (!popFront(currentJobId, runningQueue))
            {
                currentJobId = -1;
                SEQAN_ASSERT(serializer.error != NULL);
                if (serializer.error != NULL)
                    throw *serializer.error;
                return EOF;
            }

            DecompressionJob &job = jobs[currentJobId];

            // restore putback buffer
            this->setp(&job.buffer[0], &job.buffer[0] + (job.buffer.size() - 1));
            if (putback != 0)
                std::copy(
                    &putbackBuffer[0],
                    &putbackBuffer[0] + putback,
                    &job.buffer[0] + (MAX_PUTBACK - putback));

            // wait for the end of decompression
            {
                std::unique_lock<std::mutex> lock(job.cs);
                job.readyEvent.wait(lock, [&job]{return job.ready;});
            }

            size_t size = (job.size != -1)? job.size : 0;

            // reset buffer pointers
            this->setg(
                  &job.buffer[0] + (MAX_PUTBACK - putback),     // beginning of putback area
                  &job.buffer[0] + MAX_PUTBACK,                 // read position
                  &job.buffer[0] + (MAX_PUTBACK + size));       // end of buffer

            if (job.size == -1)
                return EOF;
            else if (job.size > 0)
                return Tr::to_int_type(*this->gptr());      // return next character
        }
    }

    pos_type seekoff(off_type ofs, std::ios_base::seekdir dir, std::ios_base::openmode openMode)
    {
        if ((openMode & (std::ios_base::in | std::ios_base::out)) == std::ios_base::in)
        {
            if (dir == std::ios_base::cur && ofs >= 0)
            {
                // forward delta seek
                while (currentJobId < 0 || this->egptr() - this->gptr() < ofs)
                {
                    ofs -= this->egptr() - this->gptr();
                    if (this->underflow() == EOF)
                        break;
                }

                if (currentJobId >= 0 && ofs <= this->egptr() - this->gptr())
                {
                    DecompressionJob &job = jobs[currentJobId];

                    // reset buffer pointers
                    this->setg(
                          this->eback(),            // beginning of putback area
                          this->gptr() + ofs,       // read position
                          this->egptr());           // end of buffer

                    if (this->gptr() != this->egptr())
                        return pos_type((job.fileOfs << 16) + ((this->gptr() - &job.buffer[MAX_PUTBACK])));
                    else
                        return pos_type((job.fileOfs + job.compressedSize) << 16);
                }

            }
            else if (dir == std::ios_base::beg)
            {
                // random seek
                std::streampos destFileOfs = ofs >> 16;

                // are we in the same block?
                if (currentJobId >= 0 && jobs[currentJobId].fileOfs == (off_type)destFileOfs)
                {
                    DecompressionJob &job = jobs[currentJobId];

                    // reset buffer pointers
                    this->setg(
                          this->eback(),                                        // beginning of putback area
                          &job.buffer[0] + (MAX_PUTBACK + (ofs & 0xffff)),      // read position
                          this->egptr());                                       // end of buffer
                    return ofs;
                }

                // ok, different block
                {
                    std::lock_guard<std::mutex> scopedLock(serializer.lock);

                    // remove all running jobs and put them in the idle queue unless we
                    // find our seek target

                    if (currentJobId >= 0)
                        appendValue(todoQueue, currentJobId);

                    // Note that if we are here the current job does not represent the sought block.
                    // Hence if the running queue is empty we need to explicitly unset the jobId,
                    // otherwise we would not update the serializers istream pointer to the correct position.
                    if (empty(runningQueue))
                        currentJobId = -1;

                    // empty is thread-safe in serializer.lock
                    while (!empty(runningQueue))
                    {
                        popFront(currentJobId, runningQueue);

                        if (jobs[currentJobId].fileOfs == (off_type)destFileOfs)
                            break;

                        // push back useless job
                        appendValue(todoQueue, currentJobId);
                        currentJobId = -1;
                    }

                    if (currentJobId == -1)
                    {
                        SEQAN_ASSERT(empty(runningQueue));
                        serializer.istream.clear(serializer.istream.rdstate() & ~std::ios_base::eofbit);
                        if (serializer.istream.rdbuf()->pubseekpos(destFileOfs, std::ios_base::in) == destFileOfs)
                            serializer.fileOfs = destFileOfs;
                        else
                            currentJobId = -2;      // temporarily signals a seek error
                    }
                }

                // if our block wasn't in the running queue yet, it should now
                // be the first that falls out after modifying serializer.fileOfs
                if (currentJobId == -1)
                    popFront(currentJobId, runningQueue);
                else if (currentJobId == -2)
                    currentJobId = -1;

                if (currentJobId >= 0)
                {
                    // wait for the end of decompression
                    DecompressionJob &job = jobs[currentJobId];

                    {
                        std::unique_lock<std::mutex> lock(job.cs);
                        job.readyEvent.wait(lock, [&job]{return job.ready;});
                    }

                    SEQAN_ASSERT_EQ(job.fileOfs, (off_type)destFileOfs);

                    // reset buffer pointers
                    this->setg(
                          &job.buffer[0] + MAX_PUTBACK,                     // no putback area
                          &job.buffer[0] + (MAX_PUTBACK + (ofs & 0xffff)),  // read position
                          &job.buffer[0] + (MAX_PUTBACK + job.size));       // end of buffer
                    return ofs;
                }
            }
        }
        return pos_type(off_type(-1));
    }

    pos_type seekpos(pos_type pos, std::ios_base::openmode openMode)
    {
        return seekoff(off_type(pos), std::ios_base::beg, openMode);
    }

    // returns the compressed input istream
    istream_reference get_istream()    { return serializer.istream; };
};

// --------------------------------------------------------------------------
// Class basic_bgzf_ostreambase
// --------------------------------------------------------------------------

template<
    typename Elem,
    typename Tr = std::char_traits<Elem>,
    typename ElemA = std::allocator<Elem>,
    typename ByteT = char,
    typename ByteAT = std::allocator<ByteT>
>
class basic_bgzf_ostreambase : virtual public std::basic_ios<Elem,Tr>
{
public:
    typedef std::basic_ostream<Elem, Tr>&                        ostream_reference;
    typedef basic_bgzf_streambuf<Elem, Tr, ElemA, ByteT, ByteAT> bgzf_streambuf_type;

    basic_bgzf_ostreambase(ostream_reference ostream_)
        : m_buf(ostream_)
    {
        this->init(&m_buf );
    };

    // returns the underlying zip ostream object
    bgzf_streambuf_type* rdbuf()            { return &m_buf; };
    // returns the bgzf error state
    int get_zerr() const                    { return m_buf.get_err(); };
    // returns the uncompressed data crc
    long get_crc() const                    { return m_buf.get_crc(); };
    // returns the compressed data size
    long get_out_size() const               { return m_buf.get_out_size(); };
    // returns the uncompressed data size
    long get_in_size() const                { return m_buf.get_in_size(); };

private:
    bgzf_streambuf_type m_buf;
};

// --------------------------------------------------------------------------
// Class basic_bgzf_istreambase
// --------------------------------------------------------------------------

template<
    typename Elem,
    typename Tr = std::char_traits<Elem>,
    typename ElemA = std::allocator<Elem>,
    typename ByteT = char,
    typename ByteAT = std::allocator<ByteT>
>
class basic_bgzf_istreambase : virtual public std::basic_ios<Elem,Tr>
{
public:
    typedef std::basic_istream<Elem, Tr>&                           istream_reference;
    typedef basic_unbgzf_streambuf<Elem, Tr, ElemA, ByteT, ByteAT>  unbgzf_streambuf_type;

    basic_bgzf_istreambase(istream_reference ostream_)
        : m_buf(ostream_)
    {
        this->init(&m_buf );
    };

    // returns the underlying unzip istream object
    unbgzf_streambuf_type* rdbuf() { return &m_buf; };

    // returns the bgzf error state
    int get_zerr() const                    { return m_buf.get_zerr(); };
    // returns the uncompressed data crc
    long get_crc() const                    { return m_buf.get_crc(); };
    // returns the uncompressed data size
    long get_out_size() const               { return m_buf.get_out_size(); };
    // returns the compressed data size
    long get_in_size() const                { return m_buf.get_in_size(); };

private:
    unbgzf_streambuf_type m_buf;
};

// --------------------------------------------------------------------------
// Class basic_bgzf_ostream
// --------------------------------------------------------------------------

template<
    typename Elem,
    typename Tr = std::char_traits<Elem>,
    typename ElemA = std::allocator<Elem>,
    typename ByteT = char,
    typename ByteAT = std::allocator<ByteT>
>
class basic_bgzf_ostream :
    public basic_bgzf_ostreambase<Elem,Tr,ElemA,ByteT,ByteAT>,
    public std::basic_ostream<Elem,Tr>
{
public:
    typedef basic_bgzf_ostreambase<Elem,Tr,ElemA,ByteT,ByteAT> bgzf_ostreambase_type;
    typedef std::basic_ostream<Elem,Tr>                        ostream_type;
    typedef ostream_type&                                      ostream_reference;

    basic_bgzf_ostream(ostream_reference ostream_) :
        bgzf_ostreambase_type(ostream_),
        ostream_type(bgzf_ostreambase_type::rdbuf())
    {}

    // flush inner buffer and zipper buffer
    basic_bgzf_ostream<Elem,Tr>& zflush()
    {
        this->flush(); this->rdbuf()->flush(); return *this;
    };

    ~basic_bgzf_ostream()
    {
        this->rdbuf()->addFooter();
    }

private:
    static void put_long(ostream_reference out_, unsigned long x_);
#ifdef _WIN32
    void _Add_vtordisp1() { } // Required to avoid VC++ warning C4250
    void _Add_vtordisp2() { } // Required to avoid VC++ warning C4250
#endif
};

// --------------------------------------------------------------------------
// Class basic_bgzf_istream
// --------------------------------------------------------------------------

template<
    typename Elem,
    typename Tr = std::char_traits<Elem>,
    typename ElemA = std::allocator<Elem>,
    typename ByteT = char,
    typename ByteAT = std::allocator<ByteT>
>
class basic_bgzf_istream :
    public basic_bgzf_istreambase<Elem,Tr,ElemA,ByteT,ByteAT>,
    public std::basic_istream<Elem,Tr>
{
public:
    typedef basic_bgzf_istreambase<Elem,Tr,ElemA,ByteT,ByteAT> bgzf_istreambase_type;
    typedef std::basic_istream<Elem,Tr>                        istream_type;
    typedef istream_type &                                     istream_reference;
    typedef char                                               byte_type;

    basic_bgzf_istream(istream_reference istream_) :
        bgzf_istreambase_type(istream_),
        istream_type(bgzf_istreambase_type::rdbuf()),
        m_is_gzip(false),
        m_gbgzf_data_size(0)
    {};

    // returns true if it is a gzip file
    bool is_gzip() const                { return m_is_gzip; };
    // return data size check
    bool check_data_size() const        { return this->get_out_size() == m_gbgzf_data_size; };

    // return the data size in the file
    long get_gbgzf_data_size() const    { return m_gbgzf_data_size; };

protected:
    static void read_long(istream_reference in_, unsigned long& x_);

    int check_header();
    bool m_is_gzip;
    unsigned long m_gbgzf_data_size;

#ifdef _WIN32
private:
    void _Add_vtordisp1() { } // Required to avoid VC++ warning C4250
    void _Add_vtordisp2() { } // Required to avoid VC++ warning C4250
#endif
};

// ===========================================================================
// Typedefs
// ===========================================================================

// A typedef for basic_bgzf_ostream<char>
typedef basic_bgzf_ostream<char> bgzf_ostream;
// A typedef for basic_bgzf_ostream<wchar_t>
typedef basic_bgzf_ostream<wchar_t> bgzf_wostream;
// A typedef for basic_bgzf_istream<char>
typedef basic_bgzf_istream<char> bgzf_istream;
// A typedef for basic_bgzf_istream<wchart>
typedef basic_bgzf_istream<wchar_t> bgzf_wistream;

}  // namespace seqan

#endif // INCLUDE_SEQAN_STREAM_IOSTREAM_BGZF_H_
